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In this paper, we studied point defects induced in Bridgman-grown CdZnTe detectors doped with Indium (In), Aluminium (Al), Nickel (Ni), and Tin (Sn). Point defects associated with different dopants were observed, and these defects were analyzed in detail for their contributions to electron/hole (e/h) trapping. We also explored the correlations between the nature and abundance of the point defects with their influence on the resistivity, electron mobility-lifetime (μτ_e) product, and electron trapping time. We used current-deep level transient spectroscopy to determine the energy, capture cross-section, and concentration of each trap. Furthermore, we used the data to determine the trapping andmore » de-trapping times for the charge carriers. In In-doped CdZnTe detectors, uncompensated Cd vacancies (V_Cd^-) were identified as a dominant trap. The V_Cd^- were almost compensated in detectors doped with Al, Ni, and Sn, in addition to co-doping with In. Dominant traps related to the dopant were found at E_v + 0.36 eV and E_v + 1.1 eV, E_c + 76 meV and E_v + 0.61 eV, E_v + 36 meV and E_v + 0.86 eV, E_v + 0.52 eV and E_c + 0.83 eV in CZT:In, CZT:In + Al, CZT:In + Ni, and CZT:In + Sn, respectively. Results indicate that the addition of other dopants with In affects the type, nature, concentration (N_t), and capture cross-section (σ) and hence trapping (t_t) and de-trapping (t_dt) times. Finally, the dopant-induced traps, their corresponding concentrations, and charge capture cross-section play an important role in the performance of radiation detectors, especially for devices that rely solely on electron transport.« less